David Johnson

SIMS Analysis of Nickel-Silicon Multilayers

Lead Institution

University of Oregon

Principal Investigator

David Johnson

Project type

Exploratory Research

Nickel monosilicide (NiSi) has been identified as a key contact material for next-generation VLSI technology. NiSi is conventionally prepared through the solid state reaction of a thin Ni film with…

Addressing Challenges in Nanoscale Characterization

Lead Institution

Pacific Northwest National Laboratory

Principal Investigator

Daniel Gaspar

Project type

Large-Scale EMSL Research

Nanoscale materials offer the promise of significant advances in fields as diverse as the production, storage and efficient use of energy, sensing and environmental remediation. The characterization…

Diffusion study of a-Fe2O3/a-Cr2O3(0001) Superlattice

Lead Institution

University of Oregon

Principal Investigator

David Johnson

Project type

Exploratory Research

The heterojunction between &#61537;-Fe2O3/&#61537;-Cr2O3(0001) grown by oxygen-plasma-assisted molecular beam epitaxy (OPA-MBE) has been shown to be a good candidate for interfacial diffusion…

PREMIER CAT - Determining local composition of the interleaved ferecyrstal system (LaSe1-x)1.16(VSe2-y)n (n=2, 3, 4) using electron miscroscopy techniques.

Lead Institution

University of Oregon

Principal Investigator

David Johnson

The layered intergrowth system (LaSe1-x)1.16(VSe2-y)n (n=2, 3, 4) was prepared using the modulated elemental reactant (MER) technique. Preliminary electron probe micro-analysis (EPMA) revealed non…

EMSL Science Overview

David Johnson

Projects

SIMS Analysis of Nickel-Silicon Multilayers

Addressing Challenges in Nanoscale Characterization

Diffusion study of a-Fe2O3/a-Cr2O3(0001) Superlattice

PREMIER CAT - Determining local composition of the interleaved ferecyrstal system (LaSe1-x)1.16(VSe2-y)n (n=2, 3, 4) using electron miscroscopy techniques.